ClickHouse/src/Interpreters/MutationsInterpreter.cpp

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#include <Functions/FunctionFactory.h>
#include <Functions/IFunction.h>
#include <Interpreters/InDepthNodeVisitor.h>
#include <Interpreters/InterpreterSelectQuery.h>
#include <Interpreters/MutationsInterpreter.h>
#include <Interpreters/TreeRewriter.h>
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#include <Storages/MergeTree/MergeTreeData.h>
#include <Storages/MergeTree/StorageFromMergeTreeDataPart.h>
#include <Processors/Transforms/FilterTransform.h>
#include <Processors/Transforms/ExpressionTransform.h>
#include <Processors/Transforms/CreatingSetsTransform.h>
#include <Processors/Transforms/MaterializingTransform.h>
#include <Processors/Sources/NullSource.h>
#include <Processors/QueryPipeline.h>
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#include <Processors/QueryPlan/QueryPlan.h>
#include <Processors/QueryPlan/ExpressionStep.h>
#include <Processors/QueryPlan/FilterStep.h>
#include <Processors/QueryPlan/ReadFromPreparedSource.h>
#include <Processors/Executors/PipelineExecutingBlockInputStream.h>
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#include <Processors/Transforms/CheckSortedTransform.h>
#include <Parsers/ASTIdentifier.h>
#include <Parsers/ASTFunction.h>
#include <Parsers/ASTLiteral.h>
#include <Parsers/ASTExpressionList.h>
#include <Parsers/ASTSelectQuery.h>
#include <Parsers/formatAST.h>
#include <IO/WriteHelpers.h>
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#include <Processors/QueryPlan/CreatingSetsStep.h>
#include <DataTypes/NestedUtils.h>
namespace DB
{
namespace ErrorCodes
{
extern const int NOT_IMPLEMENTED;
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extern const int BAD_ARGUMENTS;
extern const int LOGICAL_ERROR;
extern const int UNKNOWN_MUTATION_COMMAND;
extern const int NO_SUCH_COLUMN_IN_TABLE;
extern const int CANNOT_UPDATE_COLUMN;
}
namespace
{
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/// Helps to detect situations, where non-deterministic functions may be used in mutations of Replicated*MergeTree.
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class FirstNonDeterministicFunctionMatcher
{
public:
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struct Data
{
ContextPtr context;
std::optional<String> nondeterministic_function_name;
};
static bool needChildVisit(const ASTPtr & /*node*/, const ASTPtr & child)
{
return child != nullptr;
}
static void visit(const ASTPtr & node, Data & data)
{
if (data.nondeterministic_function_name)
return;
if (const auto * function = typeid_cast<const ASTFunction *>(node.get()))
{
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/// Property of being deterministic for lambda expression is completely determined
/// by the contents of its definition, so we just proceed to it.
if (function->name != "lambda")
{
const auto func = FunctionFactory::instance().get(function->name, data.context);
if (!func->isDeterministic())
data.nondeterministic_function_name = func->getName();
}
}
}
};
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using FirstNonDeterministicFunctionFinder = InDepthNodeVisitor<FirstNonDeterministicFunctionMatcher, true>;
std::optional<String> findFirstNonDeterministicFunctionName(const MutationCommand & command, ContextPtr context)
{
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FirstNonDeterministicFunctionMatcher::Data finder_data{context, std::nullopt};
switch (command.type)
{
case MutationCommand::UPDATE:
{
auto update_assignments_ast = command.ast->as<const ASTAlterCommand &>().update_assignments->clone();
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FirstNonDeterministicFunctionFinder(finder_data).visit(update_assignments_ast);
if (finder_data.nondeterministic_function_name)
return finder_data.nondeterministic_function_name;
/// Currently UPDATE and DELETE both always have predicates so we can use fallthrough
[[fallthrough]];
}
case MutationCommand::DELETE:
{
auto predicate_ast = command.predicate->clone();
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FirstNonDeterministicFunctionFinder(finder_data).visit(predicate_ast);
return finder_data.nondeterministic_function_name;
}
default:
break;
}
return {};
}
ASTPtr prepareQueryAffectedAST(const std::vector<MutationCommand> & commands, const StoragePtr & storage, ContextPtr context)
{
/// Execute `SELECT count() FROM storage WHERE predicate1 OR predicate2 OR ...` query.
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/// The result can differ from the number of affected rows (e.g. if there is an UPDATE command that
/// changes how many rows satisfy the predicates of the subsequent commands).
/// But we can be sure that if count = 0, then no rows will be touched.
auto select = std::make_shared<ASTSelectQuery>();
select->setExpression(ASTSelectQuery::Expression::SELECT, std::make_shared<ASTExpressionList>());
auto count_func = std::make_shared<ASTFunction>();
count_func->name = "count";
count_func->arguments = std::make_shared<ASTExpressionList>();
select->select()->children.push_back(count_func);
ASTs conditions;
for (const MutationCommand & command : commands)
{
if (ASTPtr condition = getPartitionAndPredicateExpressionForMutationCommand(command, storage, context))
conditions.push_back(std::move(condition));
}
if (conditions.size() > 1)
{
auto coalesced_predicates = makeASTFunction("or");
coalesced_predicates->arguments->children = std::move(conditions);
select->setExpression(ASTSelectQuery::Expression::WHERE, std::move(coalesced_predicates));
}
else if (conditions.size() == 1)
{
select->setExpression(ASTSelectQuery::Expression::WHERE, std::move(conditions.front()));
}
return select;
}
ColumnDependencies getAllColumnDependencies(const StorageMetadataPtr & metadata_snapshot, const NameSet & updated_columns)
{
NameSet new_updated_columns = updated_columns;
ColumnDependencies dependencies;
while (!new_updated_columns.empty())
{
auto new_dependencies = metadata_snapshot->getColumnDependencies(new_updated_columns, true);
new_updated_columns.clear();
for (const auto & dependency : new_dependencies)
{
if (!dependencies.count(dependency))
{
dependencies.insert(dependency);
if (!dependency.isReadOnly())
new_updated_columns.insert(dependency.column_name);
}
}
}
return dependencies;
}
}
bool isStorageTouchedByMutations(
const StoragePtr & storage,
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const StorageMetadataPtr & metadata_snapshot,
const std::vector<MutationCommand> & commands,
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ContextMutablePtr context_copy)
{
if (commands.empty())
return false;
bool all_commands_can_be_skipped = true;
auto storage_from_merge_tree_data_part = std::dynamic_pointer_cast<StorageFromMergeTreeDataPart>(storage);
for (const MutationCommand & command : commands)
{
if (!command.predicate) /// The command touches all rows.
return true;
if (command.partition && !storage_from_merge_tree_data_part)
throw Exception("ALTER UPDATE/DELETE ... IN PARTITION is not supported for non-MergeTree tables", ErrorCodes::NOT_IMPLEMENTED);
if (command.partition && storage_from_merge_tree_data_part)
{
const String partition_id = storage_from_merge_tree_data_part->getPartitionIDFromQuery(command.partition, context_copy);
if (partition_id == storage_from_merge_tree_data_part->getPartitionId())
all_commands_can_be_skipped = false;
}
else
all_commands_can_be_skipped = false;
}
if (all_commands_can_be_skipped)
return false;
context_copy->setSetting("max_streams_to_max_threads_ratio", 1);
context_copy->setSetting("max_threads", 1);
ASTPtr select_query = prepareQueryAffectedAST(commands, storage, context_copy);
/// Interpreter must be alive, when we use result of execute() method.
/// For some reason it may copy context and and give it into ExpressionBlockInputStream
/// after that we will use context from destroyed stack frame in our stream.
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InterpreterSelectQuery interpreter(select_query, context_copy, storage, metadata_snapshot, SelectQueryOptions().ignoreLimits());
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BlockInputStreamPtr in = interpreter.execute().getInputStream();
Block block = in->read();
if (!block.rows())
return false;
else if (block.rows() != 1)
throw Exception("count() expression returned " + toString(block.rows()) + " rows, not 1",
ErrorCodes::LOGICAL_ERROR);
auto count = (*block.getByName("count()").column)[0].get<UInt64>();
return count != 0;
}
ASTPtr getPartitionAndPredicateExpressionForMutationCommand(
const MutationCommand & command,
const StoragePtr & storage,
ContextPtr context
)
{
ASTPtr partition_predicate_as_ast_func;
if (command.partition)
{
String partition_id;
auto storage_merge_tree = std::dynamic_pointer_cast<MergeTreeData>(storage);
auto storage_from_merge_tree_data_part = std::dynamic_pointer_cast<StorageFromMergeTreeDataPart>(storage);
if (storage_merge_tree)
partition_id = storage_merge_tree->getPartitionIDFromQuery(command.partition, context);
else if (storage_from_merge_tree_data_part)
partition_id = storage_from_merge_tree_data_part->getPartitionIDFromQuery(command.partition, context);
else
throw Exception("ALTER UPDATE/DELETE ... IN PARTITION is not supported for non-MergeTree tables", ErrorCodes::NOT_IMPLEMENTED);
partition_predicate_as_ast_func = makeASTFunction("equals",
std::make_shared<ASTIdentifier>("_partition_id"),
std::make_shared<ASTLiteral>(partition_id)
);
}
if (command.predicate && command.partition)
return makeASTFunction("and", command.predicate->clone(), std::move(partition_predicate_as_ast_func));
else
return command.predicate ? command.predicate->clone() : partition_predicate_as_ast_func;
}
MutationsInterpreter::MutationsInterpreter(
StoragePtr storage_,
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const StorageMetadataPtr & metadata_snapshot_,
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MutationCommands commands_,
ContextPtr context_,
bool can_execute_)
: storage(std::move(storage_))
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, metadata_snapshot(metadata_snapshot_)
, commands(std::move(commands_))
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, context(Context::createCopy(context_))
, can_execute(can_execute_)
, select_limits(SelectQueryOptions().analyze(!can_execute).ignoreLimits())
{
mutation_ast = prepare(!can_execute);
}
static NameSet getKeyColumns(const StoragePtr & storage, const StorageMetadataPtr & metadata_snapshot)
{
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const MergeTreeData * merge_tree_data = dynamic_cast<const MergeTreeData *>(storage.get());
if (!merge_tree_data)
return {};
NameSet key_columns;
for (const String & col : metadata_snapshot->getColumnsRequiredForPartitionKey())
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key_columns.insert(col);
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for (const String & col : metadata_snapshot->getColumnsRequiredForSortingKey())
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key_columns.insert(col);
/// We don't process sample_by_ast separately because it must be among the primary key columns.
if (!merge_tree_data->merging_params.sign_column.empty())
key_columns.insert(merge_tree_data->merging_params.sign_column);
if (!merge_tree_data->merging_params.version_column.empty())
key_columns.insert(merge_tree_data->merging_params.version_column);
return key_columns;
}
static void validateUpdateColumns(
const StoragePtr & storage,
const StorageMetadataPtr & metadata_snapshot, const NameSet & updated_columns,
const std::unordered_map<String, Names> & column_to_affected_materialized)
{
NameSet key_columns = getKeyColumns(storage, metadata_snapshot);
for (const String & column_name : updated_columns)
{
auto found = false;
for (const auto & col : metadata_snapshot->getColumns().getOrdinary())
{
if (col.name == column_name)
{
found = true;
break;
}
}
if (!found)
{
for (const auto & col : metadata_snapshot->getColumns().getMaterialized())
{
if (col.name == column_name)
throw Exception("Cannot UPDATE materialized column " + backQuote(column_name), ErrorCodes::CANNOT_UPDATE_COLUMN);
}
throw Exception("There is no column " + backQuote(column_name) + " in table", ErrorCodes::NO_SUCH_COLUMN_IN_TABLE);
}
if (key_columns.count(column_name))
throw Exception("Cannot UPDATE key column " + backQuote(column_name), ErrorCodes::CANNOT_UPDATE_COLUMN);
auto materialized_it = column_to_affected_materialized.find(column_name);
if (materialized_it != column_to_affected_materialized.end())
{
for (const String & materialized : materialized_it->second)
{
if (key_columns.count(materialized))
throw Exception("Updated column " + backQuote(column_name) + " affects MATERIALIZED column "
+ backQuote(materialized) + ", which is a key column. Cannot UPDATE it.",
ErrorCodes::CANNOT_UPDATE_COLUMN);
}
}
}
}
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/// Returns ASTs of updated nested subcolumns, if all of subcolumns were updated.
/// They are used to validate sizes of nested arrays.
/// If some of subcolumns were updated and some weren't,
/// it makes sense to validate only updated columns with their old versions,
/// because their sizes couldn't change, since sizes of all nested subcolumns must be consistent.
static std::optional<std::vector<ASTPtr>> getExpressionsOfUpdatedNestedSubcolumns(
const String & column_name,
const NamesAndTypesList & all_columns,
const std::unordered_map<String, ASTPtr> & column_to_update_expression)
{
std::vector<ASTPtr> res;
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auto source_name = Nested::splitName(column_name).first;
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/// Check this nested subcolumn
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for (const auto & column : all_columns)
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{
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auto split = Nested::splitName(column.name);
if (isArray(column.type) && split.first == source_name && !split.second.empty())
{
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auto it = column_to_update_expression.find(column.name);
if (it == column_to_update_expression.end())
return {};
res.push_back(it->second);
}
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}
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return res;
}
ASTPtr MutationsInterpreter::prepare(bool dry_run)
{
if (is_prepared)
throw Exception("MutationsInterpreter is already prepared. It is a bug.", ErrorCodes::LOGICAL_ERROR);
if (commands.empty())
throw Exception("Empty mutation commands list", ErrorCodes::LOGICAL_ERROR);
const ColumnsDescription & columns_desc = metadata_snapshot->getColumns();
const IndicesDescription & indices_desc = metadata_snapshot->getSecondaryIndices();
const ProjectionsDescription & projections_desc = metadata_snapshot->getProjections();
NamesAndTypesList all_columns = columns_desc.getAllPhysical();
NameSet updated_columns;
bool materialize_ttl_recalculate_only = context->getSettingsRef().materialize_ttl_recalculate_only;
for (const MutationCommand & command : commands)
{
if (command.type == MutationCommand::Type::UPDATE
|| command.type == MutationCommand::Type::DELETE)
materialize_ttl_recalculate_only = false;
for (const auto & kv : command.column_to_update_expression)
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{
updated_columns.insert(kv.first);
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}
}
/// We need to know which columns affect which MATERIALIZED columns, data skipping indices
/// and projections to recalculate them if dependencies are updated.
std::unordered_map<String, Names> column_to_affected_materialized;
if (!updated_columns.empty())
{
for (const auto & column : columns_desc)
{
if (column.default_desc.kind == ColumnDefaultKind::Materialized)
{
auto query = column.default_desc.expression->clone();
auto syntax_result = TreeRewriter(context).analyze(query, all_columns);
for (const String & dependency : syntax_result->requiredSourceColumns())
{
if (updated_columns.count(dependency))
column_to_affected_materialized[dependency].push_back(column.name);
}
}
}
validateUpdateColumns(storage, metadata_snapshot, updated_columns, column_to_affected_materialized);
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}
dependencies = getAllColumnDependencies(metadata_snapshot, updated_columns);
/// First, break a sequence of commands into stages.
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for (auto & command : commands)
{
if (command.type == MutationCommand::DELETE)
{
mutation_kind.set(MutationKind::MUTATE_OTHER);
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if (stages.empty() || !stages.back().column_to_updated.empty())
stages.emplace_back(context);
auto negated_predicate = makeASTFunction("isZeroOrNull", getPartitionAndPredicateExpressionForMutationCommand(command));
stages.back().filters.push_back(negated_predicate);
}
else if (command.type == MutationCommand::UPDATE)
{
mutation_kind.set(MutationKind::MUTATE_OTHER);
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if (stages.empty() || !stages.back().column_to_updated.empty())
stages.emplace_back(context);
if (stages.size() == 1) /// First stage only supports filtering and can't update columns.
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stages.emplace_back(context);
NameSet affected_materialized;
for (const auto & kv : command.column_to_update_expression)
{
const String & column = kv.first;
auto materialized_it = column_to_affected_materialized.find(column);
if (materialized_it != column_to_affected_materialized.end())
{
for (const String & mat_column : materialized_it->second)
affected_materialized.emplace(mat_column);
}
/// When doing UPDATE column = expression WHERE condition
/// we will replace column to the result of the following expression:
///
/// CAST(if(condition, CAST(expression, type), column), type)
///
/// Inner CAST is needed to make 'if' work when branches have no common type,
/// example: type is UInt64, UPDATE x = -1 or UPDATE x = x - 1.
///
/// Outer CAST is added just in case if we don't trust the returning type of 'if'.
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const auto & type = columns_desc.getPhysical(column).type;
auto type_literal = std::make_shared<ASTLiteral>(type->getName());
const auto & update_expr = kv.second;
ASTPtr condition = getPartitionAndPredicateExpressionForMutationCommand(command);
/// And new check validateNestedArraySizes for Nested subcolumns
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if (isArray(type) && !Nested::splitName(column).second.empty())
{
std::shared_ptr<ASTFunction> function = nullptr;
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auto nested_update_exprs = getExpressionsOfUpdatedNestedSubcolumns(column, all_columns, command.column_to_update_expression);
if (!nested_update_exprs)
{
function = makeASTFunction("validateNestedArraySizes",
condition,
update_expr->clone(),
std::make_shared<ASTIdentifier>(column));
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condition = makeASTFunction("and", condition, function);
}
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else if (nested_update_exprs->size() > 1)
{
function = std::make_shared<ASTFunction>();
function->name = "validateNestedArraySizes";
function->arguments = std::make_shared<ASTExpressionList>();
function->children.push_back(function->arguments);
function->arguments->children.push_back(condition);
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for (const auto & it : *nested_update_exprs)
function->arguments->children.push_back(it->clone());
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condition = makeASTFunction("and", condition, function);
}
}
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auto updated_column = makeASTFunction("CAST",
makeASTFunction("if",
condition,
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makeASTFunction("CAST",
update_expr->clone(),
type_literal),
std::make_shared<ASTIdentifier>(column)),
type_literal);
stages.back().column_to_updated.emplace(column, updated_column);
}
if (!affected_materialized.empty())
{
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stages.emplace_back(context);
for (const auto & column : columns_desc)
{
if (column.default_desc.kind == ColumnDefaultKind::Materialized)
{
stages.back().column_to_updated.emplace(
column.name,
column.default_desc.expression->clone());
}
}
}
}
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else if (command.type == MutationCommand::MATERIALIZE_INDEX)
{
mutation_kind.set(MutationKind::MUTATE_INDEX_PROJECTION);
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auto it = std::find_if(
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std::cbegin(indices_desc), std::end(indices_desc),
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[&](const IndexDescription & index)
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{
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return index.name == command.index_name;
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});
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if (it == std::cend(indices_desc))
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throw Exception("Unknown index: " + command.index_name, ErrorCodes::BAD_ARGUMENTS);
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auto query = (*it).expression_list_ast->clone();
auto syntax_result = TreeRewriter(context).analyze(query, all_columns);
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const auto required_columns = syntax_result->requiredSourceColumns();
for (const auto & column : required_columns)
dependencies.emplace(column, ColumnDependency::SKIP_INDEX);
materialized_indices.emplace(command.index_name);
}
else if (command.type == MutationCommand::MATERIALIZE_PROJECTION)
{
mutation_kind.set(MutationKind::MUTATE_INDEX_PROJECTION);
const auto & projection = projections_desc.get(command.projection_name);
for (const auto & column : projection.required_columns)
dependencies.emplace(column, ColumnDependency::PROJECTION);
materialized_projections.emplace(command.projection_name);
}
else if (command.type == MutationCommand::DROP_INDEX)
{
mutation_kind.set(MutationKind::MUTATE_INDEX_PROJECTION);
materialized_indices.erase(command.index_name);
}
else if (command.type == MutationCommand::DROP_PROJECTION)
{
mutation_kind.set(MutationKind::MUTATE_INDEX_PROJECTION);
materialized_projections.erase(command.projection_name);
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}
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else if (command.type == MutationCommand::MATERIALIZE_TTL)
{
mutation_kind.set(MutationKind::MUTATE_OTHER);
if (materialize_ttl_recalculate_only)
{
// just recalculate ttl_infos without remove expired data
auto all_columns_vec = all_columns.getNames();
auto new_dependencies = metadata_snapshot->getColumnDependencies(NameSet(all_columns_vec.begin(), all_columns_vec.end()), false);
for (const auto & dependency : new_dependencies)
{
if (dependency.kind == ColumnDependency::TTL_EXPRESSION)
dependencies.insert(dependency);
}
}
else if (metadata_snapshot->hasRowsTTL())
{
for (const auto & column : all_columns)
dependencies.emplace(column.name, ColumnDependency::TTL_TARGET);
}
else
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{
NameSet new_updated_columns;
auto column_ttls = metadata_snapshot->getColumns().getColumnTTLs();
for (const auto & elem : column_ttls)
{
dependencies.emplace(elem.first, ColumnDependency::TTL_TARGET);
new_updated_columns.insert(elem.first);
}
auto all_columns_vec = all_columns.getNames();
auto all_dependencies = getAllColumnDependencies(metadata_snapshot, NameSet(all_columns_vec.begin(), all_columns_vec.end()));
for (const auto & dependency : all_dependencies)
{
if (dependency.kind == ColumnDependency::TTL_EXPRESSION)
dependencies.insert(dependency);
}
/// Recalc only skip indices and projections of columns which could be updated by TTL.
auto new_dependencies = metadata_snapshot->getColumnDependencies(new_updated_columns, true);
for (const auto & dependency : new_dependencies)
{
if (dependency.kind == ColumnDependency::SKIP_INDEX || dependency.kind == ColumnDependency::PROJECTION)
dependencies.insert(dependency);
}
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}
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if (dependencies.empty())
{
/// Very rare case. It can happen if we have only one MOVE TTL with constant expression.
/// But we still have to read at least one column.
dependencies.emplace(all_columns.front().name, ColumnDependency::TTL_EXPRESSION);
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}
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}
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else if (command.type == MutationCommand::READ_COLUMN)
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{
mutation_kind.set(MutationKind::MUTATE_OTHER);
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if (stages.empty() || !stages.back().column_to_updated.empty())
stages.emplace_back(context);
if (stages.size() == 1) /// First stage only supports filtering and can't update columns.
stages.emplace_back(context);
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stages.back().column_to_updated.emplace(command.column_name, std::make_shared<ASTIdentifier>(command.column_name));
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}
else
throw Exception("Unknown mutation command type: " + DB::toString<int>(command.type), ErrorCodes::UNKNOWN_MUTATION_COMMAND);
}
/// We care about affected indices and projections because we also need to rewrite them
/// when one of index columns updated or filtered with delete.
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/// The same about columns, that are needed for calculation of TTL expressions.
if (!dependencies.empty())
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{
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NameSet changed_columns;
NameSet unchanged_columns;
for (const auto & dependency : dependencies)
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{
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if (dependency.isReadOnly())
unchanged_columns.insert(dependency.column_name);
else
changed_columns.insert(dependency.column_name);
}
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if (!changed_columns.empty())
{
if (stages.empty() || !stages.back().column_to_updated.empty())
stages.emplace_back(context);
if (stages.size() == 1) /// First stage only supports filtering and can't update columns.
stages.emplace_back(context);
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for (const auto & column : changed_columns)
stages.back().column_to_updated.emplace(
column, std::make_shared<ASTIdentifier>(column));
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}
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if (!unchanged_columns.empty())
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{
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if (!stages.empty())
{
std::vector<Stage> stages_copy;
/// Copy all filled stages except index calculation stage.
for (const auto & stage : stages)
{
stages_copy.emplace_back(context);
stages_copy.back().column_to_updated = stage.column_to_updated;
stages_copy.back().output_columns = stage.output_columns;
stages_copy.back().filters = stage.filters;
}
const ASTPtr select_query = prepareInterpreterSelectQuery(stages_copy, /* dry_run = */ true);
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InterpreterSelectQuery interpreter{
select_query, context, storage, metadata_snapshot,
SelectQueryOptions().analyze(/* dry_run = */ false).ignoreLimits()};
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auto first_stage_header = interpreter.getSampleBlock();
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QueryPlan plan;
auto source = std::make_shared<NullSource>(first_stage_header);
plan.addStep(std::make_unique<ReadFromPreparedSource>(Pipe(std::move(source))));
auto pipeline = addStreamsForLaterStages(stages_copy, plan);
updated_header = std::make_unique<Block>(pipeline->getHeader());
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}
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/// Special step to recalculate affected indices, projections and TTL expressions.
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stages.emplace_back(context);
for (const auto & column : unchanged_columns)
stages.back().column_to_updated.emplace(
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column, std::make_shared<ASTIdentifier>(column));
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}
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}
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is_prepared = true;
return prepareInterpreterSelectQuery(stages, dry_run);
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}
ASTPtr MutationsInterpreter::prepareInterpreterSelectQuery(std::vector<Stage> & prepared_stages, bool dry_run)
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{
NamesAndTypesList all_columns = metadata_snapshot->getColumns().getAllPhysical();
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/// Next, for each stage calculate columns changed by this and previous stages.
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for (size_t i = 0; i < prepared_stages.size(); ++i)
{
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if (!prepared_stages[i].filters.empty())
{
for (const auto & column : all_columns)
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prepared_stages[i].output_columns.insert(column.name);
continue;
}
if (i > 0)
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prepared_stages[i].output_columns = prepared_stages[i - 1].output_columns;
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if (prepared_stages[i].output_columns.size() < all_columns.size())
{
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for (const auto & kv : prepared_stages[i].column_to_updated)
prepared_stages[i].output_columns.insert(kv.first);
}
}
/// Now, calculate `expressions_chain` for each stage except the first.
/// Do it backwards to propagate information about columns required as input for a stage to the previous stage.
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for (size_t i = prepared_stages.size() - 1; i > 0; --i)
{
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auto & stage = prepared_stages[i];
ASTPtr all_asts = std::make_shared<ASTExpressionList>();
for (const auto & ast : stage.filters)
all_asts->children.push_back(ast);
for (const auto & kv : stage.column_to_updated)
all_asts->children.push_back(kv.second);
/// Add all output columns to prevent ExpressionAnalyzer from deleting them from source columns.
for (const String & column : stage.output_columns)
all_asts->children.push_back(std::make_shared<ASTIdentifier>(column));
auto syntax_result = TreeRewriter(context).analyze(all_asts, all_columns, storage, metadata_snapshot);
if (context->hasQueryContext())
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for (const auto & it : syntax_result->getScalars())
context->getQueryContext()->addScalar(it.first, it.second);
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stage.analyzer = std::make_unique<ExpressionAnalyzer>(all_asts, syntax_result, context);
ExpressionActionsChain & actions_chain = stage.expressions_chain;
for (const auto & ast : stage.filters)
{
if (!actions_chain.steps.empty())
actions_chain.addStep();
stage.analyzer->appendExpression(actions_chain, ast, dry_run);
stage.filter_column_names.push_back(ast->getColumnName());
}
if (!stage.column_to_updated.empty())
{
if (!actions_chain.steps.empty())
actions_chain.addStep();
for (const auto & kv : stage.column_to_updated)
stage.analyzer->appendExpression(actions_chain, kv.second, dry_run);
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auto & actions = actions_chain.getLastStep().actions();
for (const auto & kv : stage.column_to_updated)
{
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auto column_name = kv.second->getColumnName();
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const auto & dag_node = actions->findInIndex(column_name);
const auto & alias = actions->addAlias(dag_node, kv.first);
actions->addOrReplaceInIndex(alias);
}
}
/// Remove all intermediate columns.
actions_chain.addStep();
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actions_chain.getLastStep().required_output.clear();
ActionsDAG::NodeRawConstPtrs new_index;
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for (const auto & name : stage.output_columns)
actions_chain.getLastStep().addRequiredOutput(name);
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actions_chain.getLastActions();
actions_chain.finalize();
/// Propagate information about columns needed as input.
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for (const auto & column : actions_chain.steps.front()->getRequiredColumns())
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prepared_stages[i - 1].output_columns.insert(column.name);
}
/// Execute first stage as a SELECT statement.
auto select = std::make_shared<ASTSelectQuery>();
select->setExpression(ASTSelectQuery::Expression::SELECT, std::make_shared<ASTExpressionList>());
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for (const auto & column_name : prepared_stages[0].output_columns)
select->select()->children.push_back(std::make_shared<ASTIdentifier>(column_name));
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/// Don't let select list be empty.
if (select->select()->children.empty())
select->select()->children.push_back(std::make_shared<ASTLiteral>(Field(0)));
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if (!prepared_stages[0].filters.empty())
{
ASTPtr where_expression;
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if (prepared_stages[0].filters.size() == 1)
where_expression = prepared_stages[0].filters[0];
else
{
auto coalesced_predicates = std::make_shared<ASTFunction>();
coalesced_predicates->name = "and";
coalesced_predicates->arguments = std::make_shared<ASTExpressionList>();
coalesced_predicates->children.push_back(coalesced_predicates->arguments);
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coalesced_predicates->arguments->children = prepared_stages[0].filters;
where_expression = std::move(coalesced_predicates);
}
select->setExpression(ASTSelectQuery::Expression::WHERE, std::move(where_expression));
}
return select;
}
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QueryPipelinePtr MutationsInterpreter::addStreamsForLaterStages(const std::vector<Stage> & prepared_stages, QueryPlan & plan) const
{
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for (size_t i_stage = 1; i_stage < prepared_stages.size(); ++i_stage)
{
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const Stage & stage = prepared_stages[i_stage];
for (size_t i = 0; i < stage.expressions_chain.steps.size(); ++i)
{
const auto & step = stage.expressions_chain.steps[i];
if (i < stage.filter_column_names.size())
{
/// Execute DELETEs.
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plan.addStep(std::make_unique<FilterStep>(plan.getCurrentDataStream(), step->actions(), stage.filter_column_names[i], false));
}
else
{
/// Execute UPDATE or final projection.
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plan.addStep(std::make_unique<ExpressionStep>(plan.getCurrentDataStream(), step->actions()));
}
}
SubqueriesForSets & subqueries_for_sets = stage.analyzer->getSubqueriesForSets();
if (!subqueries_for_sets.empty())
{
const Settings & settings = context->getSettingsRef();
SizeLimits network_transfer_limits(
settings.max_rows_to_transfer, settings.max_bytes_to_transfer, settings.transfer_overflow_mode);
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addCreatingSetsStep(plan, std::move(subqueries_for_sets), network_transfer_limits, context);
}
}
QueryPlanOptimizationSettings do_not_optimize_plan;
do_not_optimize_plan.optimize_plan = false;
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auto pipeline = plan.buildQueryPipeline(
do_not_optimize_plan,
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BuildQueryPipelineSettings::fromContext(context));
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pipeline->addSimpleTransform([&](const Block & header)
{
return std::make_shared<MaterializingTransform>(header);
});
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return pipeline;
}
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void MutationsInterpreter::validate()
{
if (!select_interpreter)
select_interpreter = std::make_unique<InterpreterSelectQuery>(mutation_ast, context, storage, metadata_snapshot, select_limits);
const Settings & settings = context->getSettingsRef();
/// For Replicated* storages mutations cannot employ non-deterministic functions
/// because that produces inconsistencies between replicas
if (startsWith(storage->getName(), "Replicated") && !settings.allow_nondeterministic_mutations)
{
for (const auto & command : commands)
{
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const auto nondeterministic_func_name = findFirstNonDeterministicFunctionName(command, context);
if (nondeterministic_func_name)
throw Exception(
"ALTER UPDATE/ALTER DELETE statements must use only deterministic functions! "
"Function '" + *nondeterministic_func_name + "' is non-deterministic",
ErrorCodes::BAD_ARGUMENTS);
}
}
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QueryPlan plan;
select_interpreter->buildQueryPlan(plan);
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auto pipeline = addStreamsForLaterStages(stages, plan);
}
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BlockInputStreamPtr MutationsInterpreter::execute()
{
if (!can_execute)
throw Exception("Cannot execute mutations interpreter because can_execute flag set to false", ErrorCodes::LOGICAL_ERROR);
if (!select_interpreter)
select_interpreter = std::make_unique<InterpreterSelectQuery>(mutation_ast, context, storage, metadata_snapshot, select_limits);
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QueryPlan plan;
select_interpreter->buildQueryPlan(plan);
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auto pipeline = addStreamsForLaterStages(stages, plan);
/// Sometimes we update just part of columns (for example UPDATE mutation)
/// in this case we don't read sorting key, so just we don't check anything.
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if (auto sort_desc = getStorageSortDescriptionIfPossible(pipeline->getHeader()))
{
pipeline->addSimpleTransform([&](const Block & header)
{
return std::make_shared<CheckSortedTransform>(header, *sort_desc);
});
}
BlockInputStreamPtr result_stream = std::make_shared<PipelineExecutingBlockInputStream>(std::move(*pipeline));
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if (!updated_header)
updated_header = std::make_unique<Block>(result_stream->getHeader());
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return result_stream;
}
const Block & MutationsInterpreter::getUpdatedHeader() const
{
return *updated_header;
}
const ColumnDependencies & MutationsInterpreter::getColumnDependencies() const
{
return dependencies;
}
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size_t MutationsInterpreter::evaluateCommandsSize()
{
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for (const MutationCommand & command : commands)
if (unlikely(!command.predicate && !command.partition)) /// The command touches all rows.
return mutation_ast->size();
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return std::max(prepareQueryAffectedAST(commands, storage, context)->size(), mutation_ast->size());
}
std::optional<SortDescription> MutationsInterpreter::getStorageSortDescriptionIfPossible(const Block & header) const
{
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Names sort_columns = metadata_snapshot->getSortingKeyColumns();
SortDescription sort_description;
size_t sort_columns_size = sort_columns.size();
sort_description.reserve(sort_columns_size);
for (size_t i = 0; i < sort_columns_size; ++i)
{
if (header.has(sort_columns[i]))
sort_description.emplace_back(header.getPositionByName(sort_columns[i]), 1, 1);
else
return {};
}
return sort_description;
}
ASTPtr MutationsInterpreter::getPartitionAndPredicateExpressionForMutationCommand(const MutationCommand & command) const
{
return DB::getPartitionAndPredicateExpressionForMutationCommand(command, storage, context);
}
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bool MutationsInterpreter::Stage::isAffectingAllColumns(const Names & storage_columns) const
{
/// is subset
for (const auto & storage_column : storage_columns)
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if (!output_columns.count(storage_column))
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return false;
return true;
}
bool MutationsInterpreter::isAffectingAllColumns() const
{
auto storage_columns = metadata_snapshot->getColumns().getNamesOfPhysical();
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if (stages.empty())
throw Exception(ErrorCodes::LOGICAL_ERROR, "Mutation interpreter has no stages");
return stages.back().isAffectingAllColumns(storage_columns);
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}
void MutationsInterpreter::MutationKind::set(const MutationKindEnum & kind)
{
if (mutation_kind < kind)
mutation_kind = kind;
}
}